|Publication number||US7142977 B2|
|Application number||US 10/838,915|
|Publication date||Nov 28, 2006|
|Filing date||May 4, 2004|
|Priority date||Nov 5, 2001|
|Also published as||DE60231319D1, EP1442443A1, EP1442443B1, US20040243298, WO2003041031A1|
|Publication number||10838915, 838915, US 7142977 B2, US 7142977B2, US-B2-7142977, US7142977 B2, US7142977B2|
|Inventors||Olli Knuuttila, Juha Nykopp|
|Original Assignee||Elisa Oyj|
|Export Citation||BiBTeX, EndNote, RefMan|
|Patent Citations (15), Non-Patent Citations (1), Referenced by (29), Classifications (11), Legal Events (5)|
|External Links: USPTO, USPTO Assignment, Espacenet|
This application is a Continuation of PCT application serial number PCT/FI02/00837 filed on Oct. 29, 2002 which claims priority to FI20012139 filed on Nov. 5, 2001 both of which are incorporated herein by reference in their entirety.
The invention relates to collection of traffic data with the aid of a network of mobile stations.
It has proved necessary to follow the speeds of means of transport, especially vehicles used in road traffic. A particular need has been evident as regards avoidance of traffic jams and road planning, whereby vehicle-specific data collection performed in real time will allow statistic analysing of the traffic as well as a comparison of performance.
Good methods exist for following spot speeds, for example, the police use radars in their traffic control. Besides these, it is possible to use measuring loops reacting to vehicles driving over them. However, neither radars nor measuring loops are able to individualise the vehicle, and it is not possible to measure e.g. reliable average speeds.
For example, in the Helsinki region picture identification methods have been used in connection with traffic data collection. At a road section a camera is placed to take pictures of passing vehicles. At another place along the road another camera is situated to take corresponding pictures. An analysing system, which may be close to real time at best, identifies the licence plates of the vehicles in the pictures. When both cameras have taken a picture of the same licence plate, it is possible reliably to determine the average speed of the vehicle in the picture. In Holland they have also connected a speeding ticket printout device to the analysing system to print out payment orders to the persons in possession of the speeding motorcars.
When real-time traffic data is desired from the area of a large road network, the picture identification method described above has such drawbacks as big investments, because it is expensive to build and maintain the measuring points. In addition, data transmission connections cost money, and the calculation capacity needed for picture identification is not either free. The method is also exposed to weather conditions, which reduces usability especially in countries where much rain, snow or fog will occur.
It has long been known to use a network of mobile stations to localise the subscriber. Using a network of mobile stations also for collection of traffic information is very well known. In the following, reference is made to two publications, U.S. Pat. No. 5,933,100 and WO 01/23835, as the state of the art.
The U.S. Pat. No. 5,933,100 shows how measurement data of a GPS system is transmitted by a mobile station to a data system, which calculates the average speed on each road section in the road network.
In PCT application publication WO 01/23835 special software is located on the terminal equipment to follow the changing of cells in the network of mobile stations and to report on the changes to the system. In one embodiment, the system computes the location of the mobile station and the speed of the mobile station based on the location of the base transceiver station and on the distance between the terminal equipment and the base transceiver station.
In another embodiment (pages 61–63 of the PCT publication) it is proposed that the location of the mobile station can be collected from the base transceiver stations in flight. The information to be collected may concern e.g. periodic beacon transmissions from the terminal equipment to the network. It is also mentioned in the application publication that the location of the mobile station may travel through the service switching point of the mobile station system, whereby the above-mentioned periodic beacon transmissions may be collected from the traffic in the service switching point.
In view of the equipment belonging to the users of the mobile station system, the solution presented in application publication WO 01/23835 does not seem operable, but it contains fundamental problems. Firstly, the terminal equipment is required to transmit extra messages to the network, which will cause unnecessary loading of the air interface in areas with much traffic. In addition, the unnecessary traffic will add to the power consumption of the terminal equipment. Secondly, the presented solution requires changes to the terminal equipment, e.g. mounting of an additional application, which means that the solution cannot be implemented with the existing mobile stations and that the same implementation will not necessarily function on the terminal equipment of two different manufacturers. Thirdly, collecting messages of the network will not necessarily succeed, if some messages travel in a protected form.
Thus, the known art gives no solution model for a method and system, wherein traffic data is collected by using a mobile station system without changes to be made in ordinary mobile stations or without necessary actions by the user. In addition, one of the most difficult problems of the state of the art relates to protection of the individual. The user's privacy is jeopardised, if his movements are being tracked, even allowing that such tracking is for the public good. If such a system is used for collecting traffic data, wherein the users are identifiable, then consent by the users is required even in the smallest possible case. It would be difficult if a user would not give his consent when such generally applicable methods are worked out, which concern all users of the network.
The objective of the invention is to bring about a solution, by which the problems presented above are eliminated. This is achieved by using the method or system according to the independent claims. From the network such areas are sought, wherein the user's terminal equipment and the network exchange messages relating to the area. The user's time of arrival in the first area is stored in accordance with the signalling used by the network and the terminal equipment. Then the stored time of arrival is compared with the user's time of arrival in another area, which is obtained correspondingly as the result of signalling carried on between the network and the terminal equipment. From this time information the time is obtained, which the terminal equipment has used for travelling between two points.
If several users are moving in the area, the measures described above may be taken e.g. on all pieces of terminal equipment occurring at the place. From the time sets thus stored statistic distributions are obtained, which can be used for determining e.g. the average speed and divergences of the traffic occurring on the connection sector.
Tracking the identity of the subscriber is a problem in the mobile station system. For example, in the GSM system, use of the user's IMSI identity (International Mobile Subscriber Identity) is usually avoided for reasons to do with data security and protection of the individual, whereby the IMSI is replaced by a TMSI identity (Temporary Mobile Subscriber Identity), which will change according to the known criteria, e.g. as the updating area changes. In one embodiment of the invention the changing of TMSI identities is tracked in order to find out the user's arrival in another area. As the TMSI identification is used in the implementation of the invention, it is not necessary to find out the interdependence of IMSI and TMSI from the network's register.
With the aid of the invention it is possible to determine location pairs or even entire grid networks, which are needed in order to obtain traffic data. The location pairs or the grid network may be determined either with the aid of a signal analyser by combining the data available from signal analysing and e.g. localising data of a satellite or mobile telephone network or by analysing radio measurement data relating to the areas to be determined from the signalling traffic of the mobile station network.
For example, areas wherein the location area changes may be areas in mobile station systems. The solution in accordance with the invention may be implemented in practice by following the signalling relating to the changing of the system's location areas. Obviously, the invention is not limited to GSM or UMTS mobile station systems only, but within the scope of the inventive idea defined in the claims the invention may also be applied to other network implementations allowing user movements, for example, to a packet-switched network of the GPRS or WLAN style, where arrival in the area or departure from the area can be noticed e.g. from transmissions relating to the changing of the routing area of the packets.
In the following, the principles of the invention will be presented with references by way of example to the enclosed drawings, wherein
Implementation of the invention is successful e.g. in a mobile station system of the kind shown in
Mobile station 101 is located in a PLM network, which is a GSM network in the present case. As a general rule, the mobile station is connected to the network through a radio interface, wherein the base transceiver stations (BTS) located in the network form cells (111–125). Each base transceiver station is connected to some base station controller (BSC) 104, 105 located in the network, either directly or by chaining through other base transceiver stations.
The base station controller controls the operation of the radio network and regulates the radio frequencies and time slots used by the mobile stations and base transceiver stations, which are the terminal equipment. The base station controller makes the required decisions based on the measurement results transmitted by the various network elements and terminal equipment. In addition, the base station controller routes further the traffic arriving from base transceiver stations to the mobile switching centre (MSC) 103. A visitor location register (VLR) 102 is arranged in connection with the mobile switching centre. The VLR keeps a record of the users located in the area and of the services ordered for them.
Co-operation between the various parts of the system is needed for routing the call or message arriving for mobile station 101. Originally it has been necessary to search the home location register (HLR) of the subscriber using the mobile station for the identity of the switching centre serving the subscriber. Then, when the call or message has been routed to the appropriate MSC 103, MSC asks VLR 102, in which part of the radio network the subscriber is located. VLR returns the location area identity (LA). Then MSC sends a paging command to BSC 104. BSC commands the relevant base transceiver stations to page the user. To avoid having to search a very large geographical area, for example, the whole country, when paging the subscriber—as the subscriber is usually well localised somewhere—the radio network is divided into location areas. Several location areas may belong to the area of one base station controller.
The mobile telephone follows the broadcast control channel (BCCH) audible in the cell. This channel has information about, among other things, the frequencies and identifiers used by the cell and its adjacent cells, about the frequency hopping order to be used and about paging groups.
The terminal equipment measures the transmission of cells having the strongest audibility, which cells are listed in the BCCH channel of the host cell of that moment. According to the GSM definitions, the terminal equipment decodes, besides the host cell, the six cells having the strongest audibility and from which the BCCH channel is being tracked. When the signal strength of the cell used by the terminal equipment becomes sufficiently weaker than the signal strength of a new cell with better audibility, the terminal equipment will change cell.
The terminal equipment listens to the BCCH channel, for example, with intervals of about 4 s. The cell's identifier is the cell's global identity (CGI), besides which the location area identity (LAI) of the cell is obtained from the BCCH channel. As can be seen in
If the location areas are located in areas of different VLRs, then the following steps must be taken in addition to those described above: 3′) the new VLR seeks user information from the old VLR, 3″) the new VLR seeks user information from HLR. Besides this, 3′″) MS and the new VLR attend to safety procedures, 5) the new VLR updates the changed VLR information for HLR and 6) HLR cancels the old location either after finding out that the location area has changed or if the old VLR requests it to cancel the location specification.
In order to avoid back-and-forth changing of the location area there is a special hysteresis mechanism for the changing of location area, that is, the location area is not changed immediately upon the change of the location area defined for the area of the cell having the strongest audibility, but there is a wait until the difference in signal strength is big enough. The operator himself can usually determine the cell reselection hysteresis parameter needed between location areas, for example, within a range of 0–14 dB. By way of default value, some equipment suppliers use a value of 6 dB.
In the selection of location area the messages 1), and 2) transmitted by the terminal equipment should in principle be provided with the subscriber's identity (IMSI, International Mobile Subscriber Identity). Likewise, the messages 4) transmitted to the terminal equipment should be addressed to the subscriber using IMSI. As it is possible to listen to the air interface, hostile quarters could track users of the mobile station network unknown to the users. In order to prevent this a pseudo identity is used, a Temporary Mobile Subscriber Identity (TMSI), which to an outside observer appears to be a random number. The relation between TMSI and IMSI is preserved in VLR and in the telephone.
The operator may select the criteria upon the fulfilment of which the TMSI is changed. For example, calls starting out from the terminal equipment or changes of the location area may result in updating of the TMSI. Updating is carried out by an encrypted message, wherein the new TMSI is transmitted in an encrypted language. The terminal equipment receives the message and decrypts the encrypted TMSI using its own encryption key, whereupon the terminal equipment begins using the new TMSI.
Based on the TMSI it is not possible to find out the user's identity (that is, the IMSI), unless there is a possibility to examine the contents of the VLR or of the subscriber identity module located in the terminal equipment.
Some operators do not use the TMSI, whereby IMSI is used in messages passing over the radio interface, which is a risk to data security. In addition, some operators have modified the updating criteria for TMSI in such a way that TMSI is updated more seldom. When the user is on the move, this too is a risk to security. In technical terms, a subscriber identity, which can be tracked, is without significance from the viewpoint of the invention, except that implementation becomes easier when the subscriber identity remains unchanged.
The basic principle of the invention emerges from
If anyone of the above location update messages is picked up from the traffic between the base transceiver station and the VLR, it can be seen that the user, whose identity is TMSI1, is at spot S3 at the time T3. If the TMSI update messages and the corresponding location update messages are also picked up from the traffic between location area 212 and the base transceiver stations and VLR, it can be seen that the identity TMSI2 has been at spot S2 earlier at the time T2. And it could have been seen from messages arrived even earlier from location area 213 that spot S1 had been passed by even at the time T1, whereby the identity TMSI3 was a temporary subscriber identity.
The situation is easier if the TMSI does not change. The system can then be set to track e.g. users arriving in areas S1 and S3. When the same identity is observed first at S1 and then at S3, it is possible to conclude that the user has been moving along the road over the distance S1–S3. The same procedure may be used, if IMSI or a static TMSI is used in the message traffic, but anonymity can then not be said to be quite as complete, but the mobile station is being tracked to some extent.
It has been found out in tests that the location update areas (S1, S2, S3) remain constant with a good accuracy, because in practice the resolution is approximately 100–300 metres. Weather conditions or the location of the telephone in the vehicle have only a minor effect on the location update areas, because the location areas on both sides of the location update area usually suffer from a radio environment of the same type. The resolution is mainly dependent on the gauge length of BCCH channel measurements made by the terminal equipment, which thus is in a class of 4 s.
As is seen from
The invention may be implemented by building, for example, a system in accordance with
Alternatively, the solution may be implemented by also using elements of the signal analyser 352 type, which are connected through points P3 to follow the traffic between the base station controller and the service switching point 303 or the VLR 302. Since data transmission systems use transmission lines with a higher capacity for individual connections, which are at a higher level in the network topology, and since connections at a higher level in the topology also cause larger framing of the signalling traffic, the system will hereby be a little heavier as a whole.
The solution can also be implemented by making the necessary changes in the base transceiver stations, in the base station controllers, in the service switching point or in the VLR. Hereby the address to which information is to be sent about the messages to be tracked is also determined for the element in question, besides the messages to be tracked. However, this alternative requires changes to the existing hardware architecture, which will often cause more costs and longer delivery times. However, implementation of this alternative is possible in connection with the version update of network elements.
When the signal analyser 351 detects a message of the desired type based on the identifier therein, it will send to the address of a predetermined server 350 the time and information contained in the message, besides the predetermined information. The server's address may be, for example, an IP address or some other network address of the server, with which a gate may be associated, to which the message is directed. The signal analyser may also transmit further as such the message it has detected.
As predetermined information there need not be other than the signal analyser's, the base station controller's, some base transceiver station's address or the location area's identity. It is not necessary to transmit the time, because in a non-congested network the time of arrival of the information in the server 350 can also be used as the time of occurrence. Of the information contained in the message at least the mobile station's identity is desired, which depending on the case is either TMSI or IMSI. In addition, in an advantageous embodiment the location area's identity and the message type are also transferred. In an advantageous embodiment the changing of TMSI identities is also tracked, besides the changes of location areas.
The traffic data calculation server 350 receives the update messages of the location area. The update messages may also be processed in their order of arrival by FIFO buffering, whereby new subscribers are added to the tracking, when such a subscriber identity arrives at some measuring point, which has not been detected earlier. Correspondingly, messages relating to identities corresponding to identities, which are already being tracked, may be used directly in order to calculate the time difference and the speed. Based on the update messages information is stored, for example, in a traffic database 355 connected to the server. The traffic database LTK is implemented as a real time database, which may be used with subscriber connections of the CORBA type. The calculation server 350 may be available through the Internet or in ways of connection defined separately. For this purpose, the calculation server is provided with protocols 360 allowing handshaking, which may be e.g. HTTP or FTP. The server may also be timed to transmit the result of analyses periodically, whereby the transmission interval can be set separately for each road section. Hereby the information of road sections with much traffic is updated more often than the information of areas with less traffic. Criteria relating to the quantity of events may also be set as the update interval.
Database 355 (
If the operator uses TMSI identifiers, a record is kept of these as well (C, D). TMSI identifiers can be detected from the traffic between the base transceiver station and the BSC or correspondingly from the messages on their way to the MSC/VLR.
The road section's kilometre reading (E, F) corresponding to each change of location area is also needed. Kilometre readings may be stored e.g. beginning from the place where the road begins by travelling the route in the measuring direction with a calibrating vehicle and by recording the distance as the location update takes place. Correspondingly, recording of the distance can be made automatic, if the vehicle's place can be stored as a function of time or even simultaneously as a function of time and place, for example, using a GPS locator. It is then sufficient to use the signal analyser to collect the TMSI identifiers of the mobile station connected to the calibrating vehicle, and by comparing the time stamps of messages the location is obtained in the GPS coordinates. Points corresponding to the road network of Finland are obtained with good accuracy from the coordinates by using e.g. a digital map base.
The following is a study of the observation of one means of transport in a case where the vehicle is travelling along main road four from the south to the north. The example is explained with references to
When moving in the example from location area 214 to location area 213 the time by the clock of the observed Location Update Request message was 04:45 a.m. and the subscriber's TMSI was A1. Then the Location Update Complete is observed in the same cell and almost with the same time by the clock, but TMSI A1 has then changed to A7. Changes of the TMSI occurring in the same signalling connection are recorded in their own auxiliary table together with time stamps. When the subscriber arrives in the place of change between the location areas 213 and 212, that is, in area S2, the signal analyser will supply to the traffic data server the time by the clock 05.25 a.m. from the location update request it has observed and the old area's identifier 213 as well as the TMSI A7. Then Location Update Complete is observed in the same cell and almost with the same time by the clock (05:26 a.m. in the example), but TMSI A7 has changed to A74. When A74 of TMSI appears once again in some other part of the network, more information is again obtained about the mobile station's movement and speed. Location Update Complete and Location Update Request with the same TMSI thus form a central part for determining the movement of the mobile station.
In the example, the time by the clock is used in the time calculator, but in a similar manner any such system can be used, which is suitable for measuring the time with sufficient accuracy. Hereby some time stamp will replace the time by the clock.
When the first observation was such a change of the location area, that 213 became the new location area, and the second observation was such a change of the location area that 212 became the new location area, the direction can be concluded, that is, that the change 214→213 corresponds with point S1 and 213→212 corresponds with point S2. Then it can be seen directly from the kilometre section (E) of the database that the distance of area S1 from the beginning of the road is 70 km and the distance of area S2 is 140 km, whereby the distance between the areas S1 and S2 is 70 km. In addition, it is possible to calculate the time spent by the vehicle for the distance, that is, 40 minutes. Obviously, there is no bad traffic jam on the road, as the average speed obtained for the means of transport is 70 km/40 min=105 km/h.
It was proposed in the foregoing that the points of change of area can be found out by doing separate measurements on the road by observing the exchange of messages between the terminal equipment and the base transceiver stations and by measuring e.g. the location of the terminal equipment using GPS localisation. The procedure is suitable for individual road sections, but it involves much work when it is desirable to make a grid network covering a large road network. The grid required for collecting road traffic data may also be collected e.g. by a signal analyser from the traffic of a SDCCH channel (Standalone Dedicated Control Channel) by catching measurement results transmitted by the mobile station to the base station controller. The terminal equipment transmits the results of signal strength measurements of the cell selected in connection with the location update request and of the six adjacent cells having the strongest audibility, using which it is possible to find out the place of the mobile station with sufficient accuracy for collecting road traffic data by using, for example, the methods described in the U.S. patent publication U.S. Pat. No. 6,052,598. The following steps are e.g. correlating the measurement results with the digital road map base, taking from it a kilometre reading corresponding with the concerned place on the road and storing the location area identities and the kilometre reading in the database. In this manner it is possible to collect grid points even of a large road network in an automated manner by collecting measurement results during a sufficient period of time, in order to obtain adequate statistics. By repeating the measurement from time to time the grid network is updated, whereby when the location of base transceiver stations is changed it is possible to eliminate the statistical error effect caused by moving location areas. Analysing of the signalling traffic may be done for terminal equipment moving along the road in both directions in a manner corresponding to analysing done separately along the road, that is, by utilising information from the old location area, whereby specific points corresponding to the place on the road are obtained for the traffic moving in each direction.
In the foregoing, the invention was described applied to a GSM mobile station network for illustrative purposes, but the intention is not to have this interpreted as any limitation of the invention. For example, it is not necessary to use location areas located one after the other, if you want to find out the time spent for travelling a distance, but it will suffice to track one IMSI/TMSI or to keep a record of TMSI changes during a time between at least two crossings of location area borders, which may even be located far from one another. Likewise, the invention may be applied in accordance with the independent claims to various cellular networks and to other wireless networks, from which a useable mechanism can be found for observing messages dependent on the areas. For example, for tracking terminal equipment in a GPRS network it is possible to utilise the change information of the routing area. The invention is also directly applicable to UMTS systems and to WLAN systems of various types, not to mention other applicable networks.
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|Aug 2, 2004||AS||Assignment|
Owner name: OY RADIOLINJA AB, FINLAND
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